JPH02215515A - Device of adjusting die lip for extrusion molding - Google Patents

Abstract

PURPOSE:To make the title device so as not to have a play due to a backlash of a screw of an adjusting bolt, by constituting the title device so that after a position of a stud bolt is adjusted so that a gap of a die lip has fixed dimensions, pressure of a fixed direction is applied to an adjusting bolt always with reaction force of a coned-disc spring. CONSTITUTION:A holding block 103 holding an adjusting bolt is fixed to an external part of a die main body 101. A stud bolt 105 is screwed in the opposite surface of a flow path surface of a flexible lip 101' a coned-disc spring 108 is inserted into the undersurface of a collar part 124 provided on the other end and a screw seat 107 is screwed in a screw hole 125 of the holding block 103 to give spring force. A large diameter adjusting bolt 110 where a small diameter adjusting bolt 109 is screwed into an inner diameter side is provided outward of the holding block 103 and a stationary nut 111 screwed into an outer diameter side screw is fixed to the holding block 103 through a press plate 112. After the coned-sisc spring 108 is set free by slackening a screw seat 107, fine adjustment of a tip position of the stud bolt 105 is performed by the tip of the small diameter adjusting bolt 109 by turning the large diameter adjusting bolt 110. Then the screw seat 107 is tightened and adjustment is performed by giving necessary spring force to the coned-disc spring 108.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a die lip adjustment device for extrusion molding that can be used in a non-stretched film (or sheet) manufacturing device, a stretched film manufacturing device, and the like.

(Prior Art) An example of a conventional die lip adjusting device for extrusion molding will be described with reference to FIGS. 3 and 4. First, in FIG. 3, a flexible lip 13 and a fixed lip 14 are formed at the tips of the die bodies 11 and 12, and a lip gap 15 is formed on the opposing surfaces of the two lips 13 and 14. In addition, a plurality of thermal displacement units 16 are provided at the tip of the die body 11 and at the protrusion above the flexible lip 13 in the width direction of the lip gap 15, and a heat insulating plate 17 is placed between them and the die body 11. One side is fixed with a bolt 18, the other side is a free end, and a through hole is provided in the longitudinal direction.

19 is a washer for adjusting the thickness of the heat insulating plate 17. A heater 20 and a thermocouple 21 are inserted into the thermal displacement unit 16, and a die bolt 2 screwed onto the upper surface of the flexible lip 13 is inserted into the thermal displacement unit 16.
2 passes through this and the die body 11 with a gap, and the die bolt 22 is fixed to the thermal displacement unit 16 with a screw 31 and a presser 32.

Further, as shown in FIG. 4, the thermal displacement unit 16 includes:
One end (not shown) is connected to an air source, and the other end (not shown) is inserted with a closed air supply pipe 24.
4 has a hole 25 at a position facing the die bolt 22, and this hole 25 communicates with an air supply port 26 connected to a die bolt through hole of the thermal displacement unit 16. On the other hand, Daiboru 2
2 is sealed at the bottom by a sealing material 27 and at the top by a presser foot 32, and is provided with a horizontal hole 28 and a vertical hole 29 communicating with the horizontal hole 28 at a position facing the air supply port 26. Therefore, the air supplied to the air supply pipe 24 is connected to the hole 25 and the air supply port 2.
6 and flows into the outer periphery of the die bolt 22, from where it passes through the horizontal hole 28 and the vertical hole 29 and is discharged to the outside.

In such a configuration, the thermal displacement unit H6 is connected to the heater 2
When heated by zero, it thermally expands and stretches upward. At this time, the die bolt 22 also receives heat from the heater 20, but since the outer periphery and the internal vertical hole 29 are cooled by air, the amount of thermal expansion thereof is smaller than that of the thermal displacement unit H6, and the upper end is the thermal displacement unit. It is fixed to 16. Therefore, the upper end of the die bolt 22 is lifted by the thermal displacement unit 16, and the flexible lip 13 is accordingly bent upward, that is, the lip gap 15 is widened, and the flow rate of the molten resin is increased. At this time, the die bolt 22 is air-cooled, so it is slightly heated, and this heat is transferred from the flexible lip 13 to the molten resin inside, and the heat of the thermal displacement unit 16 is transferred to the die through the heat insulating plate 17. It is transmitted from the main body 11 to the molten resin, lowering its viscosity and tending to increase the flow rate of the molten resin.

On the other hand, when the power supply to the heater 20 is cut off, the thermal displacement unit 16
is contracted, and the die bolt 22 is also contracted. At this time, since the die bolt 22 is constantly cooled, the amount of thermal change (shrinkage) is smaller than that of the thermal displacement unit 16, so the flexible lip 13 is pushed by the die bolt 22 and bends downward, so that the lip gap 15 The flow rate of molten resin flowing through decreases. On the other hand, since the die bolt 22 is not heated, the flexible tube 13 is cooled, the viscosity of the molten resin increases, and the flow rate tends to decrease compared to when the thermal displacement unit 16 is heated.

Next, FIG. 5 shows another conventional example, in which reference numerals 11 to 15 are the same as in the conventional example shown in FIG. 3 described above. Here, to explain the difference between FIG. 5 and FIG. 3, one side of the plurality of thermal displacement units 51 is screwed and fixed to the die body 11, and the other side is a free end. Further, 52 is a die bolt, one end of which is in contact with the upper surface of the flexible lip 13 and the other end is fixed to the free end side of the thermal displacement unit 51 by screwing, and a seal 53 is provided at the lower end of the die bolt.
It is kept airtight. 54 is a heater, and a thermocouple (not shown) is provided therein. Further, an air supply pipe 56 attached to the die body 11 via a frame 55 is connected to an air supply port 58 of the thermal displacement unit 51 through a pipe 57.
is open to a horizontal hole 60 communicating with the vertical hole 59 of the die bolt 52.

(Problem to be Solved by the Invention) In the conventional device described above, the die bolt (lip adjustment bolt) is indirectly heated by a thermal displacement unit (heating unit), so the responsiveness of expansion and contraction of the adjustment bolt is was gradual.

In addition, a large space is required to install the unit, and the distance between the adjustment bolts becomes large. In addition, if manual adjustment of push and pull is not possible, or if a manual adjustment device for push and pull is provided, there is a drawback that play occurs when changing from push to pull due to bank lash of the screw. Furthermore, in the case where the heater is used for both pushing and pulling, if the heater breaks at only one location, the adjustment bolt will contract greatly, and there is a risk that excessive force will be applied and it will break.

The present invention was proposed to solve the above problems.

(Means for Solving the Problems) Therefore, the present invention provides a die lip adjustment device for pushing and pulling a plurality of lips provided in the lip width direction of a die for extrusion molding a molten resin sheet (or film). A stud bolt that is fastened to the die lip and has a tail on the other end for installing a disc spring, a disc spring inserted into the lower part of the tail of the stud bolt, and a disc spring inserted into the stud bolt to press the disc spring. A screw seat screwed into the mating die body, a large diameter adjustment bolt with threads with different pitches on the inner and outer diameter sides, and a screw seat screwed into the inner diameter side of the large diameter adjustment bolt and above the stud bolt. It is equipped with a small diameter adjustment bolt installed so as to come into contact with the end face, and a nut screwed into the outer diameter side thread of the same large diameter adjustment bolt and fixed to the die body via a presser plate, and the adjustment bolt is attached to the die body. It is installed by inserting it from the top surface, and is intended as a means to solve the problem.

(Function) Place the tip of the small-diameter adjustment bolt screwed into the inside diameter side of the large-diameter adjustment bolt inserted from the top surface of the die body so that it abuts the upper end surface of the stud bolt, and press the screw seat and adjustment bolt together. After pulling and adjusting the position of the stud bolt so that the die lip gap is the specified size, tighten the screw seat to compress the disc spring by the specified amount, and the reaction force of the disc spring will cause the adjustment bolt to remain constant at all times. Apply force in the same direction to avoid play due to bank lash of the adjusting bolt screw.

(Embodiments) The present invention will be described below with reference to embodiments of the drawings. FIGS. 1 and 2 show embodiments of the present invention.

In FIG. 1, a resin flow path 120 is formed by combining the die body 101 and the die body 102, and the flexible lip 101' at the tip of the die body 101 and the die body 102 are combined.
2 forms a resin discharge port 121. Further, a holding block 103 for holding an adjustment bolt is fixed to the outside of the die body 101 by a bolt 119.

Further, a stud bolt 105 is attached to a heat insulating material 134 (
(ceramic screw parts or stainless steel edge inserts)
It is screwed in through a heat insulating plate 135 and fixed by a lock nut 106. Further, the other end of the stud bolt 105 is provided with a tail portion 124 for installing the disc spring 108, and is inserted into a screw hole 125 drilled in the holding block 103. A disc spring 108 is inserted into the lower surface of the flange 124, and the screw seat 10 is inserted in order to apply spring force to the disc spring 108.
7 is screwed into the screw hole 125 of the holding block 103.

Additionally, a small diameter adjustment bolt 1 is provided on the outside of the holding block 103.
A large-diameter adjustment bolt 110 with a screw thread 09 screwed into the inner diameter side is provided, and a fixing nut 111 is attached to the outer diameter side of the large-diameter adjustment bolt 110 (the pinch is different from the inner thread).
is screwed in, and the fixing nut 111 is held down by the holding plate 11.
Retaining block 10 by bolt (not shown) through 2
It is fixed and installed at 3. Note that the holding plate 112 is divided into parts so as to hold the fixing nuts 1112 over each other.

Said adjustment pole) 109.110 and fixing nut 111
In combination, the small diameter adjustment bolt 109 has a detent pin 11.
3 is installed so that it does not rotate with respect to the holding block 103, and the fixing nut 111 is also fixedly installed on the holding block 103 so that it does not rotate, making it a differential screw type adjustment bolt and holding the screw seat 107. After loosening the block 103 to free the disc spring 108, turn the large diameter adjustment bolt 110 to finely adjust the tip of the small diameter adjustment bolt 109, and finely adjust the tip position of the stud bolt 105. Manual adjustment is performed by tightening the screw seat 107 and applying the required spring force to the disc spring 108.

On the other hand, a heater 10 for heating the stud bolt 105
4 is made into a cylindrical shape, has an inner diameter processed so as to fit on the outer periphery of the stud bolt 105, and is installed on the outer periphery of the stud bolt 105. Further, a heat insulating material 118 is provided between the heater 104 and the die body 101 to minimize heat transfer between the two. In addition, 117 in the figure is a heat insulating plate, which connects the flexible lip 101' and the die body 10.
It substantially seals the gap 123 surrounded by the flange portion 122 of 1, and also serves as a heat insulator to prevent heat radiation from the stud bolts 105 and the like. 114 is an exhaust jacket, and heater 1 for heating the stud bolt 105
An air supply port is provided to provide an air supply passage for cooling the die 04 and to isolate the heater 104 from the outside air. Air is supplied from the heater 104 through the hole 115-1, which is suitably drilled throughout, through the air passage 115-2, and from the lower ventilation hole 115-3 to the outer periphery of the heater 104. The air is exhausted through the exhaust port 116 while cooling the heater 104. By cooling the heater 104 in this manner, the stud bolt 105 is also cooled.

Next, to explain the operation of the embodiment configured as above, the adjustment bolt device has the stud pole (05) and adjustment pole (109 and 110) separated into separate bodies.
Although the pulling force due to the screw cannot be applied, the disc spring 108
Since the adjustment bolt 1 is provided to apply force in the pulling direction,
When turning 09.110 in the loosening direction, a pulling force is applied to the stud bolt 105 by the force of the disc spring 108. The force and amount of adjustment by this disc spring 108 can be adjusted as appropriate by increasing or decreasing the number of disc springs in parallel and in series, so it is only necessary to select and install the required number (Figure 1 shows two disc springs). (This shows the case where two sets of parallel stacks are combined in series).

In addition, in the case of automatic adjustment by heating and cooling the stud bolt 105, when the stud bolt 105 is heated and expanded,
The upper end of the same stud bolt 105 is a small diameter adjustment pole) 109
Since the upper end is held down by the stud bolt 10
5 becomes a force pushing the flexible lip 101' as it is, and when the stud bolt 105 is cooled and contracted, the upper end of the stud bolt 105 moves away from the adjustment bolt 109, but due to the force of the disc spring 108, the upward pushing force is As a result, a force acts in the direction of pulling the flexible lip 101', allowing both pushing and pulling. In addition, adjustment bolts 109, 110
Since force is always applied in the same direction by the disk spring 108, there is no play in the screw when switching between pushing and pulling.

In addition, the stud bolt 105 and the adjustment bolt 10 with screws
9. Since the part 110 is a separate body, even if only one heater is disconnected and the stud bolt 105 contracts a lot, it will be absorbed by the amount of deflection of the disc spring 108. No force greater than the reaction force is applied, and it is possible to prevent damage to the adjustment poles 109 and 110 when the heater breaks, which is the biggest problem in the case of both push and pull. In addition, by installing the holding plate 112 that holds the fixing nut 111 in two pieces for each nut,
If a problem occurs with the adjustment bolts 109, 110 or the heater 104, it becomes easy to replace only one of them.

The above description is based on the case where the heater 104 is provided.
It goes without saying that the device of this embodiment can be used only with a manual gap adjustment device in which the heater 104, the heat insulating plate 118, and the air supply/exhaust jacket 114 are removed.

(Effects of the Invention) As described above in detail, the present invention has one end of the stud bolt fastened to the die lip, and the other end of which abuts against the small diameter adjustment bolt screwed into the inner diameter side of the large diameter adjustment bolt that can be pushed and pulled. As a result, manual adjustment of the lip can be performed accurately and easily. In addition, since the large and small diameter adjustment bolt and the stud bolt are separated, the pulling force cannot be applied by the screw, but since a disc spring is provided to apply the pulling force, when the adjusting bolt is turned in the loosening direction. Due to the force of the disk spring, a pulling force is applied to the stud bolt.

In addition, the adjustment bolt is always applied with force in the same direction by the disc spring, so there is no play in the screw when switching between pushing and pulling.

Note that heating time can be shortened by inserting the stud bolt into the heater, and cooling time can be shortened by direct air supply and exhaust to the outer circumference of the heater. , it is possible to improve the responsiveness of the expansion and contraction of the stud bolt, that is, the responsiveness of the push/pull adjustment of the flexible lip.Furthermore, when automatically adjusting the stud bolt by heating and cooling,
When the stud bolt is heated and expanded, the upper end of the stud bolt is held down by the small diameter adjustment bolt, so the expansion of the stud bolt directly becomes a force pushing the die lip, and when it cools and contracts, the upper end of the stud bolt is pressed down by the small diameter adjustment bolt. The die lip moves in the direction away from the die lip, but since it is pressed upward by the force of the disc spring, the force is applied in the direction of pulling the die lip (it can be used for both pushing and pulling. Even if only one of the stud bolts breaks and the stud bolt shrinks significantly, it will be absorbed by the amount of deflection of the disc spring, so no force greater than the reaction force of the disc spring will be applied, and the maximum It is possible to prevent damage to the adjustment bolt when the heater breaks, which is an issue in Even if a problem occurs in one, it is easy to replace just one.

[Brief explanation of the drawing]

FIG. 1 is a side sectional view of a die lip adjusting device for extrusion molding according to an embodiment of the present invention, FIG. 2 is a view taken along arrow A in FIG. 1, and FIG. 3 is a side sectional view of a conventional die lip adjusting device. Figure 4 is the third
FIG. 5 is a side sectional view showing another conventional die lip adjusting device. Description of main parts in the figure 101--Die body 101'--Flexible lip 102--Die body 103--Holding block 105--Stud bolt 106--Lock nut 107--Screw seat 108- - Disc spring 109 - Small diameter adjustment bolt 110 - Large diameter adjustment bolt 111 - Fixing nut 112 - Holding plate 113 - Stopper bottle 120 - Resin flow path 121 - Resin discharge port 123 -・Gap 124 One flange 125 ---Screw hole 3P43 Figure 4 JP! Figure 5 Procedural Amendment May 10, 1989 Yoshi, Commissioner of the Japan Patent Office 1) Tsuyoshi Bun, Patent Application No. 1-36020 2, Title of Invention Die lip adjustment device for extrusion molding 3, Relationship with the person making the amendment Patent application Address 2-5-1 Marunouchi, Chiyoda-ku, Tokyo Name
(620) Mitsubishi Heavy Industries, Ltd. 4, Contents of agent date amendment 1, “114 is exhaust” on page 11, line 7 of the specification changed to “1
14 is for air supply and exhaust.'' 2. "Adjustment bolt 109.L" on page 13, line 14.
Correct loJ to [stud bolt 105]. 3. "Damage of adjustment bolt" in the first line of page 16 is corrected to "damage of stud bolt." Above 6, Column 7 for detailed explanation of the invention subject to amendment, Contents of amendment

Claims (1)

[Claims] In a die lip adjusting device that pushes and pulls to adjust multiple lips provided in the lip width direction of a die for extruding molten resin sheet (or film), one end is fastened to the die lip and a disc spring is installed at the other end. a stud bolt having a collar, a disc spring inserted into the lower part of the collar of the stud bolt, and a screw seat fitted to the stud bolt and screwed into the die body to press the disc spring;
A large diameter adjustment bolt with threads with different pitches on the inner and outer diameter sides, and a large diameter adjustment bolt that is screwed into the inner diameter side of the same large diameter adjustment bolt.
A small diameter adjustment bolt installed so as to come into contact with the upper end surface of the stud bolt, and a nut screwed into the outer diameter side thread of the large diameter adjustment bolt and fixed to the die body via a presser plate, A die lip adjustment device for extrusion molding, characterized in that an adjustment bolt is inserted and installed from the upper surface of the die body.